Method and system for spatial characterization of an imaging system

ABSTRACT

A configuration system generates a calibration target to be printed, the target including a set of machine-readable and visually-identifiable landmarks and associated location-encoding marks which encode known locations of the landmarks. A plurality of test images of the printed calibration target is acquired by the system from an image capture assembly. Positions of the landmarks in the acquired test images and the location-encoding marks in the acquired test images are detected by the system. The system decodes the locations of the landmarks from the detected location-encoding marks and spatially characterizes the image capture assembly, based on the detected positions of the landmarks in the acquired test images and their decoded known locations.

CROSS REFERENCE TO RELATED PATENTS AND APPLICATIONS

Cross-reference is made to the following copending applications, filed contemporaneously herewith: U.S. application Ser. No. 14/303,809, filed Jun. 13, 2014, entitled STORE SHELF IMAGING SYSTEM, and U.S. Application Ser. No. 14/303,724, filed Jun. 13, 2014, entitled IMAGE PROCESSING METHODS AND SYSTEMS FOR BARCODE AND/OR PRODUCT LABEL RECOGNITION, the disclosures of which are incorporated herein by reference in their entireties

BACKGROUND

The exemplary embodiment relates to spatial characterization of imaging systems and finds particular application in connection with a system and method for configuring an imaging system used for determining the spatial layout of product content of a product facility, such as a store.

Retail chains, such as pharmacy, grocery, home improvement, and others, may have a set of product facilities, such as stores, in which products are presented on product display units, such as shelves, cases, and the like. Product information is generally displayed close to the product, on preprinted product labels. The product labels indicate the price of the item and generally include a unique identifier for the product, e.g., in the form of a barcode, which is often used by the store for restocking and other purposes. The product locations often vary across each of the stores in a chain. Thus, it is often desirable to map each store individually in order to know the exact locations of the products.

Current approaches for documenting product locations on shelves include sending one or more persons through the store taking pictures along the store aisles with a mobile device, such as a cell phone camera or using webcams mounted throughout the store. Post-processing of the captured images is then used in an attempt to identify each product and its location on a shelf. In many applications, such simple, un-calibrated, and low cost surveillance cameras are more than sufficient. However, there are many applications where more detailed analysis is desired, such as for the recognition of barcodes. Knowledge about the characteristics of the imaging system and accurate configuration of the imaging system would be particularly useful for such fine-grained tasks. This would help processing, such as simplifying the algorithms used, improving robustness, providing predictable inputs for analysis, and the like.

Existing calibration procedures using standard or special targets for single monocular or stereo-vision cameras are described, for example, in Zhengyou Zhang, “Flexible Camera Calibration By Viewing a Plane From Unknown Orientations,” ICCV '99, pp. 666-673 (1999) and U.S. Pub. No. 20130342706. However, such systems often lack the ability to deal with more complex imaging systems, such as multi-camera imaging systems which may need to be reconfigured due to changes in the imaging task, such as differences in store layouts, or different constraints placed on the imaging system, such as the speed of operating the system.

There remains a need for a system and method for characterizing or configuring an imaging system, such as a store shelf imaging system, so that it is adaptable to different applications.

INCORPORATION BY REFERENCE

The following references, the disclosures of which are incorporated by reference in their entireties, are mentioned:

U.S. Pub. No. 20130342706, published Dec. 26, 2013, entitled CAMERA CALIBRATION APPLICATION, by Hoover, et al., discloses a method and system for camera calibration.

U.S. Pub. No. 20100171826, published Jul. 8, 2010, entitled METHOD FOR MEASURING RETAIL DISPLAY AND COMPLIANCE, by Hamilton, et al., discloses a method and apparatus for measuring retail store display and shelf compliance.

BRIEF DESCRIPTION

In accordance with one aspect of the exemplary embodiment, a configuration system includes a calibration target generation module which generates a spatially-characterized calibration target to be printed. The calibration target includes a set of machine-readable and visually-identifiable landmarks and associated location-encoding marks which encode known locations of the landmarks. An image acquisition module acquires a plurality of test images of the printed calibration target from an associated image capture assembly to be spatially characterized. A landmark detection module detects positions of the landmarks in the acquired test images. An information decoding module detects the location-encoding marks in the acquired test images and decodes the locations of the landmarks from the detected location-encoding marks. A spatial characterization module spatially characterizes the image capture assembly, based on the detected positions of the landmarks in the acquired test images and the respective decoded known locations of the landmarks. A processor implements the calibration target generation module, image acquisition module, landmark detection module; information decoding module, and spatial characterization module.

In accordance with another aspect of the exemplary embodiment, a configuration method includes providing a spatially-characterized calibration target, the calibration target comprising a set of machine-readable and visually-identifiable landmarks and associated location-encoding marks which encode known locations of the landmarks. For at least one iteration, the method includes acquiring a plurality of test images of the printed calibration target at a plurality of vertically-spaced positions with an image capture assembly to be spatially characterized. Positions of the landmarks in the acquired test images are detected. The locations of the landmarks are decoding from the detected location-encoding marks detected in the acquired test images. The image capture assembly is spatially characterized, based on the positions of the landmarks in the acquired test images and the decoded known locations of the landmarks.

At least one of the steps of the method may be performed with a computer processor.

In accordance with another aspect of the exemplary embodiment, a method for configuring an imaging system having a plurality of vertically-spaced fields of view includes, with a template, generating sections of a calibration target, each of the sections of the calibration target comprising a set of machine-readable and visually-identifiable landmarks and associated location-encoding marks which encode known locations of the landmarks. The sections are joined together to form the calibration target. A plurality of test images of the printed calibration target is acquired at a plurality of vertically-spaced positions with an image capture assembly. Positions of the landmarks in the acquired test images are detected. Locations of the landmarks from the detected location-encoding marks detected in the acquired test images are decoded. The image capture assembly is reconfigured, based on the positions of the landmarks in the acquired test images and the decoded known locations of the landmarks. For the reconfigured image capture assembly, the acquiring of the plurality of test images, detecting positions of the landmarks, and decoding the locations of the landmarks are repeated.

At least one of the steps of the method may be performed with a computer processor.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic elevational view of a store profile generation system in accordance with one aspect of the exemplary embodiment;

FIG. 2 is a schematic elevational view of a store profile generation system in accordance with another aspect of the exemplary embodiment;

FIG. 3 is a schematic elevational view of a store profile generation system in accordance with another aspect of the exemplary embodiment;

FIG. 4 is a schematic elevational view of a store profile generation system in accordance with another aspect of the exemplary embodiment;

FIG. 5 is a functional block diagram of the store profile generation system of FIGS. 1-4 in accordance with one aspect of the exemplary embodiment;

FIG. 6 illustrates an exemplary price tag;

FIG. 7 is a flow chart illustrating a store profile generation method in accordance with another aspect of the exemplary embodiment;

FIG. 8 illustrates a map of a store with a route for the store profile generation system identified;

FIG. 9 illustrates a configuration component, a section of a modular calibration target, and a mission-specific target;

FIG. 10 illustrates a calibration target mounted to a vertical surface being used in configuration of the exemplary a store profile generation system;

FIG. 11 is a flow chart illustrating a method for configuration and/or characterization of the image capture assembly of the store profile generation system in accordance with another aspect of the exemplary embodiment;

FIG. 12 illustrates a representation of an initial configuration of the image capture assembly;

FIG. 13 illustrates a representation of a reconfiguration of the image capture assembly; and

FIGS. 14 and 15 illustrate panoramas of the calibration target before and after reconfiguration of the image capture assembly generated from computed spatial profiles of the cameras.

DETAILED DESCRIPTION

Aspects of the exemplary embodiment relate to a configuration system and method for characterizing the spatial characteristics of an imaging system, in particular, an imaging system for use in retail applications, such as a store profile generation system.

The outputs of the exemplary configuration system, e.g., spatial profiles of the imaging system, may be used for determining product layout in real-world coordinates, for determining the path/pace of a mobile base of the shelf imaging system, and the like. The system can also be applied iteratively to reconfigure and/or optimize such an imaging system for specific settings applicable in different retail applications.

In the embodiments described below, the configuration system serves as a configuration component of a mobile profile generation system. However, it is to be appreciated that the configuration system may be a stand-alone system embodied in any suitable general purpose or dedicated computing device or used as a component of other mobile imaging systems which may need to be characterized and/or reconfigured.

With reference to FIGS. 1-5, where the same numbers are used for similar elements, a mobile profile generation system 10 is configured for determining a spatial layout 12 (FIG. 5) of the product content of a product facility, such as a retail store, warehouse, or the like. The spatial layout may be referred to herein as a store profile. The store profile 12 may be in the form of a 2-dimensional or 3-dimensional plan of the store which indicates the locations of products, for example, by providing product data for each product, such as an SKU or barcode, and an associated location, such as x, y coordinates (where x is generally a direction parallel to an aisle and y is orthogonal to it), a position on an aisle, or a position on a predefined path, such as a walking path through the store. In some embodiments, the store profile may include a photographic panorama of a part of the store generated from a set of captured images, or a graphical representation generated therefrom.

The store profile 12 is generated by capturing images of product display units 14, such as store shelf units, at appropriate locations with appropriate imaging resolutions. As illustrated in FIG. 1, each shelf unit 14 may include two or more vertically-spaced shelves 16, to which product labels 18, such as product price tags, displaying product-related information, are mounted, adjacent related products 19. In the exemplary embodiments, the price labels are not on the products themselves, but on the shelf units, e.g., in determined locations. Thus for example, a portion of a shelf which is allocated to a given product may provide for one (or more) price labels to be displayed for that product. In other embodiments the product labels 18 may be displayed on an adjacent pegboard or be otherwise associated with the respective display unit 14.

The exemplary profile generation system 10 includes a mobile base 20, an image capture assembly 22, and a control unit 24, which are moveable as a unit around the product facility. The exemplary system 10 captures images within a product facility, such as a retail store, with the image capture assembly 22 at a sequence of locations of the mobile base 20, extracts product-related data 26 (e.g., printed barcodes and/or text from the captured product price labels) and location information from the images and the mobile base location, and constructs a store profile 12 (e.g., a 2D map, as discussed above) which defines a spatial layout of locations of the shelf labels 18 within the store.

The mobile base 20 serves to transport the image capture assembly 22 around the product facility and may be fully-autonomous or semi-autonomous. In one embodiment, the mobile base 20 is responsible for navigating the system 10 to a desired location with desired facing (orientation), as requested by the control unit 24, and reporting back the actual location and facing, if there is any deviation from the request. As illustrated in FIG. 5, in a fully-autonomous mode, the motorized mobile base 20 may include a navigation component 30 and an associated power source 32, such as a battery, motor, drive train, etc., to drive wheels 34 of the of the mobile base in order to move the system 10 to a desired location with desired facing according to a request from the control unit 24. The navigation component 30 may be similarly configured to the control unit 24 and may include memory and a processor for implementing the instructions provided by the control unit and reporting location and orientation information back to the control unit. Position and/or motion sensors 36 provide the navigation component 30 with sensing capability to confirm and/or measure any deviation from the requested location and orientation. These may be used by the navigation component for identifying the location, orientation, and movement of the mobile base for navigation and for store profile generation by the control unit. One suitable mobile base which can be adapted to use herein is a Husky™ unmanned ground vehicle obtainable from Clearpath Robotics Inc., 148 Manitou Dr, Kitchener, Ontario N2C 1L3, Canada, which includes a battery-powered power source.

In a semi-autonomous mode, the mobile base 20 is pushed by a person (e.g., as a cart), and thus the power source and optionally also the navigation component may be omitted. In some embodiments, the navigation component and sensors may be used in the semi-automated mode to confirm and/or measure any deviation from a requested location and orientation (e.g., by using voice feedback to confirm the aisle/shelf information or using image features of the scene).

The image capture assembly 22 includes an imaging component 38 which includes one or more image capture devices, such as digital cameras 40, 42, 44, that are carried by a support frame 46. The image capture devices capture digital images, such as color or monochrome photographic images. The support frame may be mounted to the mobile base 20 and extend generally vertically (in the z-direction) therefrom (for example, at an angle of from 0-30° from vertical, such as from 0-20° from vertical). The cameras are configured to capture images of a full height h of the shelf unit, or at least that portion of the height h in which the labels 18 of interest are likely to be positioned throughout the facility.

One or more of the camera(s) 40, 42, 44 may be moveable, by a suitable mechanism, in one or more directions, relative to the support frame 46 and/or mobile base 20. In one embodiment, at least one of the cameras has a first position and a second position, vertically-spaced from the first position, allowing the camera to capture images in the first and second positions. In the embodiment illustrated in FIGS. 2 and 3, for example, the support frame 46 includes a translation stage 48 for moving one or more of the camera(s) in at least one direction, such as generally in the z (vertical) direction, as illustrated by arrow 49. The direction of movement need not be strictly vertical if the support translation stage is mounted to an angled support frame, as noted above. Optionally, the translation stage 48 provides for rotation of one or more of the cameras in the x, y plane and/or tilting of one or more of the cameras, relative to the translation stage/support frame. In another embodiment, the cameras, and/or their associated mountings, may provide the cameras with individual Pan-Tilt-Zoom (PTZ) capability. The pan capability allows movement of the field of view (FOV) relative to the base unit in the x direction; the tilt capability allows the field of view to move in the z direction as illustrated for camera 44 in FIG. 3; the zoom capability increases/decreases the field of view in the x, z plane (which may be measured in units of distance, such as inches or cm, as illustrated in FIG. 3, or angle α, as illustrated in FIG. 1). In some embodiments, only some, i.e., fewer than all, of the cameras are moveable and/or have PTZ capability, as illustrated in FIG. 4, where only camera 42 has such capabilities. The incremental movement of the mobile base 20 allows images to be captured along the length of the shelf unit 14 (in the x direction).

The image capture assembly 22 serves to capture a series of images containing shelf product labels 18, such as product price tags, at sufficient resolution for analysis and product recognition. The product price or tags 18 may be located on the outer edge of a shelf or at the end of a pegboard hook 50, or other product label mounting device. As illustrated in FIG. 6, each price tag 18 generally includes a unique identifier 54 for the product, such as a 1 or 2-dimensional barcode or stock keeping unit (SKU) code. As an example, a 1D EAN-13 code may be printed on or otherwise affixed to the product label. 2D barcodes are commonly referred to as QR codes or matrix codes. In addition, a human-readable price 56 and optionally some descriptive text 58 may be printed on or otherwise affixed to the product label.

A width w of the barcode 54 in the y direction may be about 20-25 mm on many price tags. However, the barcode width may not be uniform throughout the store or from one store to another. In order to allow accurate imaging and decoding of such barcodes, a minimum resolution of approximately 200 pixels per inch (ppi) (78 pixels per centimeter) at the object plane with sufficient depth of focus to allow for differences in x direction position or tilt of the price tags relative to the camera is desirable. For smaller barcodes and 2D barcodes, a higher resolution may be appropriate. A digital camera mounted to a support frame 46 so that it can be relatively stationary while capturing images is thus more suited to this task than a hand-held smartphone camera or inexpensive webcams, unless the acquisition is performed close up (e.g., one barcode at a time with the camera placed very close to the barcode) and the camera is held sufficiently steady. Furthermore, although the locations of price tags are somewhat systematic, there are large variations from shelf to shelf, store to store, and chain to chain, as well as differences in lighting conditions, print quality, transparency of the product label mounting device 50 (if it overlays the product label 18), and so forth. Thus, it may be appropriate to change the design and/or adjust the configuration of the cameras, depending on the expected conditions within the store or portion thereof. An exemplary image capture assembly 22 is adaptable to accept different numbers of cameras and/or different camera capabilities, as described in further detail below.

The exemplary control unit 24 provides both control of the system and data processing. The control unit 24 includes one or more dedicated or general purpose computing devices configured for performing the method described in FIG. 7. The computing device may be a PC, such as a desktop, a laptop, palmtop computer, portable digital assistant (PDA), server computer, cellular telephone, tablet computer, pager, combination thereof, or other computing device capable of executing instructions for performing the exemplary method. As will be appreciated, although the control unit 24 is illustrated as being physically located on the mobile base 20 (FIG. 1), it is to be appreciated that parts of the control unit may be in the image capture assembly 22 or located on a separate computer remote from the mobile base and image capture assembly.

The control unit 24 illustrated in FIG. 5 includes a processor 60, which controls the overall operation of the control unit 24 by execution of processing instructions which are stored in memory 62 communicatively connected with the processor 60. One or more input/output interfaces 64, 66 allow the control unit to communicate (wired or wirelessly) with external devices. For example, interface 64 communicates with cameras 42, 44, 46 to request image capture, and/or adjustments to the PTZ settings, and to receive captured digital images from the cameras; with translation stage 48, where present, to adjust camera position(s); with mobile base 20 for movement of the system as a whole, relative to the shelf unit, and the like. Interface 66 may be used for outputting acquired or processed images, a store profile 12, and/or information extracted therefrom, such as to an external computing device and/or a printer (not shown) for printing and/or packaging sale signage in an appropriate order to match the store profile.

The various hardware components 60, 62, 64, 66 of the control unit 24 may be all connected by a bus 68.

The memory 62 may represent any type of non-transitory computer readable medium such as random access memory (RAM), read only memory (ROM), magnetic disk or tape, optical disk, flash memory, or holographic memory. In one embodiment, the memory 62 comprises a combination of random access memory and read only memory. In some embodiments, the processor 60 and memory 62 may be combined in a single chip. The interface 66, 68 allows the computer to communicate with other devices via a wired or wireless links or by a computer network, such as a local area network (LAN) or wide area network (WAN), or the internet, and may comprise a modulator/demodulator (MODEM), an electrical socket, a router, a cable, and and/or Ethernet port. Memory 62 stores instructions for performing the exemplary method as well as the processed data 12.

The digital processor 60 can be variously embodied, such as by a single-core processor, a dual-core processor (or more generally by a multiple-core processor), a digital processor and cooperating math coprocessor, a digital controller, or the like. The digital processor 60, in addition to controlling the operation of the computer 62, executes instructions stored in memory 62 for performing the method outlined in FIGS. 7 and/or 11.

The term “software,” as used herein, is intended to encompass any collection or set of instructions executable by a computer or other digital system so as to configure the computer or other digital system to perform the task that is the intent of the software. The term “software” as used herein is intended to encompass such instructions stored in storage medium such as RAM, a hard disk, optical disk, or so forth, and is also intended to encompass so-called “firmware” that is software stored on a ROM or so forth. Such software may be organized in various ways, and may include software components organized as libraries, Internet-based programs stored on a remote server or so forth, source code, interpretive code, object code, directly executable code, and so forth. It is contemplated that the software may invoke system-level code or calls to other software residing on a server or other location to perform certain functions.

The processor 60 executes instructions 70 stored in memory 62 for performing the method outlined in FIGS. 7 and/or 11. In the illustrated embodiment, the instructions include a configuration component 74, a mission planner 76, a translation stage controller 78, a camera controller 80, an image data processing component 82, a product data recognition component 84, a store profile generator 86, and a signage generator 88. Fewer than all these components may be included in some embodiments. In other embodiments, some or all of the components may be located on a separate computing device, i.e., one which is not carried by the mobile base, as discussed above.

The configuration component 74 is used prior to a mission to configure the image capture assembly 22 (e.g., determine FOV and position(s) of the camera(s) and to provide a spatial characterization of the image capture assembly, such as a spatial profile for each camera. Each camera may have at least one camera spatial profile. A camera may have two or more spatial profiles if the camera is to be moved, relative to the mobile base, and/or its FOV adjusted, for acquiring more than one image at the same mobile base location. The camera spatial profile may be a mapping between pixel location and a location in an x, z plane to enable a mapping between pixels of each image captured at a respective camera position and a position in the x, z plane corresponding to a portion of a shelf face where the images are captured.

The mission planner 76 has access to a store floor plan 90 (layout of aisle and shelves and its facing) and the purpose of each mission. A mission may be for example, to capture all price tags throughout the store, or limited to only a part of the store, etc. Using the information in the store floor plan 90, the mission planner determines the path that the mobile base 20 should follow and communicates with the mobile base to provide the path and appropriate stop positions (where the images should be acquired by the image capture assembly). The instructions may be provided to the mobile base in a step-by-step fashion or in the form of a full mission.

The translation stage controller 78 determines the translations of the translation stage to achieve desired camera positions and communicates them to the translation stage 48. The camera controller 80 determines the camera parameters (e.g., shutter speed, aperture, ISO number, focal length, . . . ) and optionally position parameters (e.g., pan, tilt, zoom, or vertical translation amount . . . ) of the cameras in the image capture assembly for each position that requires image acquisition. These parameters may be fixed throughout the mission and/or adjusted dynamically based on current location information of the mobile base (e.g., distance to the shelf to be imaged, the facing angle, height of the shelf . . . ). As will be appreciated, translation stage controller 78 and camera controller 80 may form parts of a single component for controlling the acquisition of images by the image capture assembly 22.

The image data processing component 82 processes the images acquired by all the cameras and uses the mapping provided by the configuration component and position information provided by the mobile base to map pixels of the captured image to locations in 3D space.

The product data recognition component 84, which may be a part of the image data processing component 82, analyses the processed images for detecting price tag locations, extracting product data 26, such as price tag data, and performs image coordinate conversion (from pixel position to real-world coordinates).

Outputs of the data processing component 82 and/or product data recognition component 84 may be used by the store profile generator 88 to determine the store profile 12 (e.g., the real-world coordinates of detected and recognized UPC codes). In some cases, outputs of the data processing component 82 and/or product data recognition component 84 are used by the translation stage controller 78 and/or camera controller 80 to determine what should be the appropriate camera parameters and/or position parameters for the next image capture. Some outputs of the data processing component 82 and/or product data recognition component 84 may be used by the mission planner 76 to determine the next positional move for the mobile base 20.

With reference now to FIG. 7, a method for generating (and using) a store profile 12 is shown, which can be performed with the system of FIGS. 1-5. As will be appreciated, some or all of the steps of the method may be performed at least partially manually and need not be performed in the order described. The method begins at S100.

At S102, the image capture assembly 22 is configured. Briefly, the configuration component 74 identifies suitable positions for the cameras 42, 44, 46, and optionally a suitable range of camera parameters (e.g., field of view, exposure time, ISO number, etc.), in order to capture the full height h of each shelf unit face from a set of overlapping images acquired at one single position of the moveable base (i.e., without gaps in the z direction). The configuration component 74 optionally extracts information from test images which enables it to associate each (or some) pixels of a captured image with a point in yz space and/or to generate a spatial characterization of the image capture assembly which may include a spatial profile for each camera.

At S104, a route for scanning the store shelves is computed. In particular, the mission planner 76 computes a route for the mobile base around the facility, based on a store floor plan 90. The floor plan identifies obstructions, particularly locations of shelf units. The store plan may have been generated partially automatically, from a prior traversal of the facility by the system 10, for identifying the location of obstructions. For example, as shown in FIG. 8, the obstructions may be identified on the floor plan 90 and locations of scannable faces 92 on each shelf unit identified (e.g., by a person familiar with the store). The mission planner 76 computes a route 94, which includes all the faces 92 and designates parts of the route as a scan path 96 (where images of scannable faces 92 are to be acquired) and parts of the route as a no-scan path 98 (where no images are to be acquired).

At S106, the mission planner 76 communicates the computed route 94 to the navigation component 30 of the mobile base, and optionally designating stop positions, which may be located at approximately equal intervals along the scan path 96. During the mission, the mission planner 76 receives information from the navigation component 30 from which any deviations to the planned route are computed. The mobile base 20 is then responsible for navigating the system 10 to a desired location with desired facing (orientation) requested by the control unit 24 and reporting back the actual location and facing if there is any deviation from the request.

At S108, as the mobile base 20 traverses the route 94, instructions are provided to the translation stage 48 at each predetermined stop on the scan path 96 for positioning the cameras. The translation stage controller 78 communicates instructions to the translation stage 48 when the camera position(s) is/are to be adjusted and may provide the translation stage 48 with directions for achieving predetermined camera positions, based on the information generated by the configuration component 74.

At S110, at each predetermined stop on the scan path 96, instructions are provided to the cameras 40, 42, 44 themselves for positioning and image acquisition. In particular, the camera controller 80 communicates instructions for adjusting position and/or focal plane to the camera's PTZ components and provides instructions for data acquisition to provide the optimal coverage of the shelf, using the position information identified by the configuration component 74. The translation stage controller 78 and camera controller 80 may work in cooperation to achieve desired positions of the cameras.

At S112 images 100, 102, are acquired by the cameras at a given position of the mobile base. The image capture assembly (iteratively) acquires images based on the requests by the control unit and the camera parameters and (optionally) position parameters provided.

At S114, the acquired images 100, 102 are transferred from the camera memory to the data processing component 82. The data processing component 82 receives the images acquired by the cameras and stores them in memory, such as memory 62, and may perform preliminary processing, such as adjustments for blur, color, brightness, etc. A composite image or panorama of the shelf face may be computed by performing a union of multiple images captured by the image capture assembly. In forming the composite image, pixels of one or more of the acquired images may be translated to account for each camera's spatial profile.

At S116, the product data recognition component 84 processes the acquired images 100, 102 or panorama to identify product data 26 from the captured shelf labels 18, where present, in the images. In an exemplary embodiment, the acquired images and a corresponding coarse location and facing information are analyzed to determine the product layout information (e.g., via barcode recognition of price tags and knowledge of the camera spatial profile).

The process repeats until the mission is completed (e.g., all aisles of interest have been scanned). For a typical mission, the mobile base moves along each store aisle to enable images of the scannable faces of each shelf unit to be captured. From the captured images, each shelf price tag is detected and its location determined within the image.

By measuring the mobile base's current position in the store floor plan, its position data can then be associated with the images being captured at that position, based on the time of capture. Candidate regions of each image 100, 102 which have at least a threshold probability of including a barcode 54 are identified and processed to extract the barcode information, which may be output as an SKU code which uniquely identifies the product. Associated information, such as price and product information 56, 58, particular colors used in the product label 18, and the like, may also be used to locate the barcode and/or to decipher it, particularly where the product data recognition component has difficulty in doing so based on the barcode alone. The location of the barcode in three dimensional space can be determined based on the location of the mobile base at the time the image was captured and the spatial characterization of the image capture assembly.

At S118, a store profile 12 is generated based on the identified barcode information 26 and computed barcode locations. In particular, the store profile generator 86 generates a store profile 12 which identifies locations of the price tags 18, based on the extracted barcode information and optionally information provided by one or more of the configuration component 74, mission planner 76, and navigation component 30, through which pixels of identified barcodes in the captured images are associated with a point in real (xyz or xy) space or otherwise generally located with respect to the store floor plan 90. An accurate store profile 12 identifying product locations/locations of price tags in a store can thus be reconstructed.

At S120, the store profile 12 may be output from the system.

At S122, information on signage to be mounted throughout the store may be received and a packaging order for the particular store computed, based on the store profile 12. In particular, the signage generator 88 receives information on signage to be printed for an upcoming sale in which only some but not all of the price tags may need to be replaced. The signage generator uses the store profile 12 to identify the locations of only the price tags/products to which the sale relates. From this information, a printing and/or packaging order for the signage is generated. When the signage is packaged and provided to an employee, the order in which the signage is packed in accordance with the computed printing and/or packaging order enables the person to traverse the store in the order in which the signage is packaged to replace/add the new signage, generally in a single pass through the store. The route defined by the packing order minimizes the amount of backtracking the employee needs to do and/or provides for a shorter path (in time or distance) to complete the task than would be achievable without the computed store-specific packaging order, and avoids the need for the store to resort the signage into an appropriate order. In this way, for each store in a chain, a store profile can be generated (e.g., periodically), allowing a store-specific packaging order for signage to be computed each time a set of shelf labels 18 and/or other signage is to be mounted throughout the store.

The method ends at S124.

Further details of the system and method will now be described.

While in one embodiment, the store profile 12 is used for defining an appropriate sequence for printing/packaging of sale signage, the store profile has other applications, including validating that the store product layout complies with a pre-defined planogram. A planogram is a predefined product layout for a slice of about 0.5 meters or more of length along an aisle. The captured images can also be processed to extract any 1D or 2D barcodes and/or text data from regions that comply with the price tag format. Data such as the product UPC and the price tag location within the image are extracted.

Image Capture Assembly

To accommodate different shelf configurations and/or acceptable acquisition times, different configurations of the image capture assembly 22 are contemplated. In one embodiment, each camera 40, 42, 44 provides for high resolution imaging in a field of view (FOV) 110 (FIG. 1) defined by an angle α at the lens or by a vertical distance at the shelf face. In another embodiment, the cameras provide a mixture of high resolution imaging (one or more cameras) and low resolution imaging (one or more cameras capturing images at a lower resolution than the high resolution camera(s)), referred to as multi-resolution imaging. The high-resolution imaging embodiment has the advantages of simpler and faster acquisition, single pass processing, and facilitation of off-line image processing. The multi-resolution imaging embodiment has the advantage of lower cost. More detailed examples of each are now discussed.

1. High Resolution Imaging for Barcode Detection and Recognition in Retail Applications

For this imaging option, few assumptions need to be made about the potential locations of price tags 18. For example, the only information needed may be the maximum height h of shelves of interest in the store. For this imaging option, there is also no iterative processing needed to estimate the barcode locations before next imaging. As a result, designing this imaging option entails confirming that the system, in aggregate, has sufficient field of view to cover the maximum height of shelves of interest in the store at the desired resolution (typically 200 ppi or above).

As an example, a DSLR camera with horizontal and vertical sensor dimensions of about 22 and 15 mm (a 3:2 aspect ratio) which has a high pixel resolution of at least 100 or at least 200 pixels/mm at the sensor (e.g., a 10 Mpixel camera or higher) can provide a minimum object plane resolution of 100 or 200 pixels/inch in a plane FOV of about 68.5 cm×45.5 cm (± about 5 or ± about 10 cm).

Since a shelving unit 14 may be around 180 cm tall, a single camera generally cannot capture it fully with a single image while meeting the resolution requirements. Several embodiments of the image capture assembly that can meet these goals are given, by way of example:

A. Multi-Camera Array

In the embodiment of FIG. 1, for example, two or more (optionally identical) cameras 40, 42, 44 are located in fixed relation to each other and to the mobile base. Each camera can have different poses (rotation, focus length etc.) if needed. The FOV of each camera is vertically spaced from its neighbor and overlaps that of its neighbor by a known amount. “Vertically spaced FOVs” means that the FOVs are spaced from each other at least partially in the z direction. Thus, a composite image of a full 180 cm tall shelving unit can be extracted from three cameras (with capabilities as described above) oriented in portrait mode spaced 60 cm apart. For different heights/camera capabilities, a different number of cameras could be used, the aim being to have enough cameras to cover the entire vertical FOV (height h) of the shelving unit faces with desired resolution in one position while the navigation of the mobile base offers the scanning needed to cover the horizontal FOV (i.e., store aisles). Since this embodiment over-specifies the image resolution requirement (i.e., to achieve high resolution everywhere, regardless the locations of barcodes in each store) and each camera operates independently, all images can be captured in a pass through the store and be processed later. Hence this embodiment offers a rapid and non-iterative acquisition. The image processing can be done in an off-line fashion allowing the system to acquire all images needed quickly and then process them later, e.g., on the same or a different computing device which may be in the back office of the store. Advantages of running the system in such a manner include (1) less disruption to store hour operation and (2) computational costs may be cheaper when the analysis of the captured images is performed on a back office computer than on an on-board computing device. A disadvantage is that more cameras may be needed than for other embodiments.

B. Camera(s) with a Moveable Positioning Unit

As illustrated in FIG. 2, fewer cameras can be used to capture the full height shelving unit than for embodiment 1A by using a vertical translation stage 48. In the embodiment, two cameras with two-position (or more) capability are used. In a first position, each camera 40, 42 captures an image, and then the translation stage moves the cameras to a second position, vertically spaced from the first position, where two more images are captured. The benefits of off-line processing and faster and non-iterative acquisition (compared to other embodiments discussed later) are retained in this embodiment. However, this embodiment, may incur the expense of additional imaging time and slight increase of system complexity. From the perspective of images captured, this embodiment is very similar to multi-camera array of embodiment 1A with lower cost but lower acquisition rate. This option can offer a flexible trade-off between cost and acquisition time. The number of positions can be extended to the extent where only a single camera is needed. In the exemplary embodiment, pictures are captured while the camera is stationary (i.e., stopped at desired positions), rather than while moving between positions, since even a slight motion during the imaging may inhibit or prevent accurate recognition of barcodes unless sophisticated motion compensation algorithms are employed. Accordingly, adding more stops by decreasing the number of camera positions/decreasing the number of cameras may increase acquisition time.

As with embodiment 1A, the system over-specifies the requirement of the imaging device/configuration such that high resolution is achieved everywhere (within the potential space of interest, e.g., no more than 2 m high in store aisles). This makes the system very adaptable to any store configuration, makes the image acquisition non-iterative and faster, and makes the processing simpler and independent from image acquisition. Given that the resolution is sufficient and the FOV covers all possible regions of interest, the data processing component 82 can focus on detecting, localizing, and recognizing the product identity through price tag recognition. Embodiment 1A is simpler but embodiment 1B may be suited to stores with specific configurations, such as taller shelves and/or those with sparse and discrete potential locations of barcodes. For this type of store, the second embodiment can cope easily with this by replacing an attempt to cover all vertical FOVs up to the maximal height with pre-programming a few discrete positions for imaging that can cover those sparse and discrete potential locations of barcodes in the selected stores. For example, in FIG. 3, cameras 40 and 42 may move between first and second positions to capture upper shelves while a third camera is tilted downward to capture a shelf near the floor level.

The pre-determined FOVs for each camera in the embodiment 1B system can be achieved by a combination of selecting a suitable distance to the shelf from the mobile base 20 and/or through the zooming capability of the cameras.

In one embodiment, the control unit 24 instructs the mobile base 20 to navigate to a fixed distance to the shelf face and keep the focus length of each camera fixed. In another embodiment, the control unit only provides the mobile base with a range of distances to the shelf for it to navigate to. Each camera then adjusts its zoom parameter to maintain the FOVs based on the actual distance to the shelf reported back from mobile base. This may be a somewhat more expensive option, due to the cost of a controllable zoom lens, but can be more adaptable. A combination of the two embodiments is also contemplated.

2. Multi-Resolution Imaging for Barcode Detection and Recognition in Retail Applications

In this embodiment, multi-resolution imaging is used to accomplish the task of identifying the store profile 12. In this embodiment, the system first captures low resolution, large FOV images, analyzes them to identify regions of interest (ROIs) that may require high imaging resolution (i.e., may include barcodes). The system then acquires high resolution images of those regions, and analyzes them for extracting product identification information, where present. The spatial information for these ROIs can be determined based on a combination of the camera spatial profiles of the low resolution images and mobile base location information or a combination of camera spatial profiles of the high resolution images and mobile base location information. The former may be a better and easier option since the camera spatial profiles of the high resolution images may be more dynamic and vary from acquisition to acquisition.

The terms low and high resolution are used herein in a relative sense. High resolution generally refers to a sufficient resolution to recognize a barcode robustly (e.g., 200 ppi or higher), while low resolution refers to sufficient resolution to detect candidate/potential locations of a barcode (e.g., 30 ppi or higher). The desired resolution can be achieved in a number of ways. For example, the high and low resolutions can be achieved by a same type of camera but with different FOVs. In another example, the high and low resolution can be achieved primarily by the use of high vs. low camera sensor resolutions (e.g., using 20 Mega-pixel camera for high resolution imaging and a 2 Mega-pixel camera for low resolution imaging). In another example, a combination of FOV and camera sensor resolution can be used to achieve the high and low resolution imaging system.

A. Single Camera with PTZ Capability

In one embodiment (not illustrated), the image capture assembly 22 includes only a single camera with PTZ capability as the image capture device. The camera may be a PTZ camera or a regular camera with PTZ base. In this embodiment, the camera may first zoom-out and take a picture or pictures with a large FOV to cover the full height of the shelf. The images are analyzed to find candidate regions of interest (ROIs) which are more likely to include price tags than other regions of the images. In general, finding potential locations of price tags requires much less resolution than extracting the product information from each price tag. The camera then zooms in to various identified ROIs to acquire high resolution images to be used for extracting product identification information. The mobile base 20 is then moved to its next position along the shelf face and the process is repeated. Since the camera FOVs are constantly changing, it can be difficult to keep track of the spatial profiles of the camera and/or to ensure that the store has been completely scanned (for at least those regions of interest). The imaging may also take a long time since the imaging is in iterative fashion (the low resolution images are first acquired and analyzed before performing high resolution imaging) and many camera zoom-ins and zoom-outs may be needed. However, this embodiment can be constructed at relatively low cost. A person could walk around the store taking close-up pictures of the shelf labels 18 in a similar fashion. However, the system offers the automation and location tracking (through the mobile base navigation and control unit's mission planning) that could not be performed easily by a person.

B. High/Low Camera Combination with PTZ Capability

In the embodiment shown in FIG. 4, two cameras 40, 42 having different imaging parameters are used. A first camera 40 is used to acquire low resolution, but large FOV images of the entire shelf face. As for embodiment 2A above, the purpose of this camera is to allow the control unit 24 to identify local ROIs where shelf price tags are suspected of being present. Given one or more of these ROIs, the second camera 42 is used to acquire high resolution images of the identified ROIs before the mobile base 20 is moved to its next position along the shelf face. The second camera 42 may have PTZ capability (a PTZ camera or a regular camera mounted on a PTZ motorized base 48). The first camera generally does not need such capability if the FOV is sufficient to cover the shelf height at the lowest resolution needed for prediction of ROIs. The imaging parameters of the first camera 40 may be fixed throughout the mission (no need for PTZ capability). This helps to ensure that the spatial profile of the first camera is constant (and thus can be derived offline) throughout the mission. By doing so, it is easy to determine the spatial layout of those identified ROIs based on the combination of the camera spatial profiles of the low resolution images and mobile base location information. This also avoids the need to keep track of the imaging parameters of the second camera when scanning through those identified ROIs.

This imaging embodiment reduces the need for processing high resolution images since processing is performed only on images captured of the ROIs, rather than of the entire shelf face. It may need to use more complex and iterative imaging acquisition modes to process the mixed resolution images. The cost and image processing time may be reduced (since for most of the time, many small images with high resolution are processed rather than a one extremely large composite high resolution image or set of images). However, it adds complexity to the method by increasing image acquisition time and may require on-line image processing.

In practice, the imaging embodiment selected may be application dependent. For example, a store with densely-populated price tags may benefit from high resolution imaging of the entire shelf face. In contrast, a store with sparse and irregularly-placed price tags may benefit from multi-resolution imaging. Mission time and cost also play a role for the selection of imaging options. The exemplary system can be configured to cover the typical spectrum experienced by a majority of the retail stores.

Although the imaging is described above as being high-resolution or multi-resolution, it should be appreciated that the imaging system may provide a combination of these approaches. For example, it may be beneficial to have PTZ camera(s) mounted on a moveable translation stage. In this embodiment, the translation stage is responsible for moving the PTZ camera to various coarse positions, while the PTZ capability of the camera is responsible for fine-tuning the FOVs to the desired resolution specification, focus, and the like.

Configuration

The configuration component 74 of the system 10 provides for automatic characterizing of the spatial characteristics of the image capture assembly 22 and for configuring of the data processing component 82. The outputs, e.g., spatial profiles of the imaging system, may be used by the store profile generator 86 for determining product layout in terms of real-world coordinates, for determining the path/pace of the mobile base 20, and the like. The configuration component can be applied iteratively to configure/optimize the image capture assembly 22 for the specific setting of each retail application.

As illustrated in FIG. 9, the configuration component may include a calibration target generation module 120, a mission-specific target generation module 122, an image acquisition module 124, a landmark detection module 126, an information decoding module 128, a spatial characterization module 130, a mission capability confirmation module 132, and a reconfiguration module 134, although fewer than all of these modules may be provided in some embodiments.

The calibration target generation module 120 includes instructions (e.g., a template) for generating a spatially-characterized calibration target 140 (FIG. 10), when printed on sheets of paper by a communicatively linked printer 142, or otherwise output in tangible form. The calibration target 140 may be sectional and composed of a plurality of sections 146 (FIG. 9), which when assembled sequentially in a predefined order, form a target 140 of sufficient height to cover the portion h of the shelf face where product tags 18 are expected to be found. In other embodiments, the target 140 may be printed as a continuous length which may be cut to size at the store.

As illustrated in FIG. 9, each of the sections 146 has a width W (in a direction corresponding to the x direction, during a mission) and a height H in the z direction. The sections 146 may be taped or otherwise joined together to overlap at 148 to form a target 140 with a width W and a height h (FIG. 10). Each section 146 includes a plurality of machine-readable, visually-identifiable landmarks 150 with known positional information. In the illustrated embodiment, the landmarks are equally sized and spaced at predetermined intervals 154, 156 in W and H directions, respectively, to form a grid. Each section 146 includes an identical set of landmarks 150. The positional information may be encoded by a set of machine readable and visually recognizable location-encoding marks 158 which encode locations of the landmarks 150. The marks 158 may each be located adjacent the corresponding landmark 150 or positioned on the landmark itself. In the exemplary embodiment, the locations of the landmarks are encoded by human-readable identifiers, such as numbers, in the location-encoding marks 158. Each section 146 may include a human readable identifier 160, such as the section number, which assists a person in assembling the sections in the correct order and orientation to form the target.

The mission-specific target generation module 122 includes instructions for generating examples of one or more printable mission-specific targets 164, which may be combined with the calibration target 140. Additionally, known target information may be encoded by a second set of machine readable and visually recognizable marks (mission-info-encoding marks). In particular, the target 164 may be representative of the product tags to be identified in the store, and include, for example, a barcode 166 similar in size to the barcodes on the product tags 18, and/or or other machine readable information. The mission-specific targets 164 may be printed on one or more of the sections 146 or on separate sheets of paper, to be positioned, for example, adjacent to or on the target (FIG. 10). As will be appreciated, the generation of the calibration target and mission specific targets may be performed offline, prior to configuration of the system, and these components may be part of a separate computing device and not resident on the moveable system.

The image acquisition module 124 acquires test images using the image capture assembly 22 to be spatially characterized and/or configured. As will be appreciated, the camera controller 80 and stage controller 78 (FIG. 5) may serve as the image acquisition module 124 and/or may communicate with module 124 for acquiring the test images of the target(s) 140, 164.

The landmark detection module 126 detects the identifiable landmarks 150 and their positions on the acquired images of the target 140.

The information decoding module 128 detects the set(s) of machine readable and visually-recognizable marks 158, 166 on the acquired images of the target(s) 140, 164 and then decodes the corresponding locations of identifiable landmarks 150 from the associated location-encoding marks. Information 166 from the mission-specific targets in the images may also be decoded.

The spatial characterization module 130 matches the positions of landmarks 150 detected by module 128 to the actual positions on the target 140 and then derives absolute and relative spatial profile(s) and other characteristics of the imaging system.

The mission capability confirmation module 132 analyzes the acquired images to extract information from the mission-specific image targets 164, such as from the example barcodes 166, and compares this against the known information of the image targets, to determine whether the information matches (e.g., determine if the barcode captured in the image can be read to generate a SKU number corresponding to the known SKU number of the printed barcode 166). This allows the module 132 to confirm/assess the capability of the system to perform the mission. In the case where the barcode cannot be read correctly, the module 132 outputs information to the configuration computation module 134.

The reconfiguration module 134 may utilize some or all of the following information to compute a new configuration for the image capture assembly 22: the characterized spatial profile(s) of the imaging system, the knowledge of the parameters of the current configuration of the imaging system, and the knowledge of the system requirements (which may be mission dependent, store dependent, application-dependent, etc.). The module 134 may compute a modified (improved) configuration for the image capture assembly 22, e.g., one which is able to capture more of the shelf face 92 and/or provide sufficient resolution to capture barcode information from the product price tags 18.

FIG. 11 illustrates an exemplary configuration process, which can be performed with the modules of FIG. 9. The method begins at S200.

At S202, mission-specific targets 164 may be generated by module 122, in cooperation with an associated printer 142. At S204, a calibration target 146 is generated by module 120, in cooperation with an associated printer 142. Step S202 may be incorporated into the generation of a calibration target which includes the mission specific target(s).

At S206, test images are acquired by module 124, in cooperation with the image capture assembly 22.

At S208, landmarks are detected in the acquired test images by the module 126.

At S210, the information 158, 166 in the acquired test images is decoded, where possible, by the module 128.

At S212, the image capture assembly 22 is spatially characterized, by the module 130.

At S214, the capability of the system 10 for performing the mission is assessed, by the module 132, based on information provided by the modules 128, 130.

At S216, a reconfiguration of the image capture assembly 22 is computed by the component 134, which may be output to the stage controller 78 and/or camera controller 80 for reconfiguring the image capture assembly 22. If at S218, a reconfiguration of the image capture assembly 22 has been made, the method may then return to S206 for another iteration of the system configuration, otherwise, the method may proceed to S104, where a mission is commenced.

Further details of the configuration of the image capture assembly 22 will now be described.

Calibration Target Generation (Off-Line Process)

Module 120 generates sections (e.g., in the form of printer recognizable instructions) which are used for forming a spatially characterized target 140 (FIG. 9), which includes an arrangement (e.g., an array) of identifiable landmarks 150 with known positional information encoded by a set of machine readable and visually recognizable marks 158. The physical calibration target 140 is generated for characterizing the image capture assembly 22, including cameras 40, 42, 44 and moveable components 48.

The modularity of the target facilitates scalability and ease of deployment in different facilities. For example, one store may have a maximum shelf face of about 100 cm and may use from 3 to 6 sections 146 (depending on their height) to form the calibration target 140. Another store may have a maximum shelf face of 180 cm and may use from 7 to 10 sections 146 to form the calibration target 140. The use of marks 158 which are both machine readable and visually recognizable allows for automation or human operation and allows for reduction in human and/or algorithmic errors.

As an example, the modular sections 146 may be designed to fit on sheets of paper which are a standard paper size, such as A3 (29.7×42 cm), A4 (29.7×21 cm), tabloid (27.94×43.18 cm), or letter-size (21.59×27.94 cm), used by the printer 142.

The landmarks 150 may be circular black dots or other regular shapes of the same size and shape, which are easily identifiable marks for a computer and a human to recognize. Their corresponding known relative locations are encoded by a corresponding set of machine readable and visually recognizable marks 158 which may be made more-recognizable by a colored box in which a number is located. The color choices for the marks 150, 158 may be selected to facilitate automated image processing. A first digit of the location-encoding mark 158 may correspond to a number of the section 146 (section 1 in the illustrated embodiment, with each section having a different number in sequence). A second digit or digits may provide a unique identifier for the landmark which is associated in memory 62 with a location of the corresponding landmark on the target. However, other machine-readable marks are also contemplated. For example, the location-encoding marks 158 could each be implemented as a 1D or 2D barcode. Optionally, horizontal and vertical grid lines 168 are provided to help human operators to perform measurements visually.

A calibration target 140 which is a composite of four sections 146 is shown in FIG. 10. The four sections may have been taped together to form the target which is then temporarily affixed to a shelving unit 14, wall, or other suitable vertical planar surface 170. Each section includes an identical set of landmarks 150 in which each column of landmarks is vertically aligned with the corresponding column of landmarks from the adjacent section(s). However, the location-encoding marks 158 are different in each section to reflect the different starting height of each the sections.

A template for generating the sections 146 may be designed using Microsoft PowerPoint or other suitable software, where the relative position encoding and ID 160 of the section is implemented as a page number variable.

The maximal height h that the image capture assembly 22 to be characterized needs to capture in a single position of the mobile base is determined and an n-page document is created using the template by printing or copying the page. The sections are taped, glued or otherwise assembled together and the target is mounted to the wall 170, e.g., with tape. In some cases, a bottom blank region 172 of the lowermost section may be trimmed so that the first row of black dots is a predetermined height above, or level with, the floor or other predetermined position. Alternatively, an offset may be used in computation to allow for the bottom blank region of this section. The bottom blank regions 172 of the rest of the pages may be used as the interface region to attach the pages together.

The exemplary calibration target 140 is assembled in order of the page numbers, starting from the bottom of the wall. The relative and absolute location information of each of the black dots in the final composite target can then be decoded. For example, the images are processed using optical character recognition (OCR) software to identify the marks 158 within the detected boxes just above each dot and a formula is applied to compute the actual location, in the x, z plane, of each dot. In an example embodiment, for the target illustrated in FIG. 10, the following formula may be used:

$\begin{matrix} {x = \left\{ {{\begin{matrix} {{- 3}d_{0}} & {d_{0} = {0\text{∼}4}} \\ {{- 3}\left( {d_{0} - 5} \right)} & {d_{0} = {5\text{∼}9}} \end{matrix}\mspace{14mu}\left( {{for}\mspace{14mu}{horizontal}{\mspace{11mu}\;}{direction}} \right)z} = \left\{ {\begin{matrix} {6 + {9\left( {d_{1} - 1} \right)}} & {d_{0} = {0\text{∼}4}} \\ {3 + {9\left( {d_{1} - 1} \right)}} & {d_{0} = {5\text{∼}9}} \end{matrix}\left( {{for}\mspace{14mu}{vertical}\text{/}{height}\mspace{14mu}{direction}} \right)}\mspace{11mu} \right.} \right.} & {{Eq}.\mspace{14mu}(1)} \end{matrix}$

where, d₀ is the last digit of the numerical text in each colored box and d₁ are the remaining digit(s) of the numerical text in the colored box. This equation is suited to the case where the relative positions of 10 black dots arranged in two rows are encoded in the last digit in the template using d₀=0˜9, while d₁ is encoded as the page number. d₁ automatically increases by one for each page of the multiple-page document. As will be appreciated, for different arrangements and locations, different formulae may be used to compute the actual locations of each of the landmarks detected in test images of the target. In general, each section may include at least two vertically spaced rows, each row comprising at least 2 or at least 3 landmarks that are horizontally spaced.

The modular design and encoding scheme for the example target 140 make it easy to deploy in any retail store, since it can be readily generated using a standard printer and tape. In one embodiment, the template for forming the sections may be stored on a portable memory storage device, such as a disk, flash memory, or downloaded to a local computer, allowing it to be used at the store location to generate the template. With distinct colors and shapes for the marks 150, 158, the detection module 126 can detect the marks robustly.

By making the targets human readable as well as machine readable, a human is able to assist in the reconfiguration of the image capture component 22. For example, the image capture assembly 22 may provide for live view of the captured images. A human can use the camera live view of the calibration target to roughly reconfigure the image capture assembly 22 close to desired state, with the assistance of the ruler-like target and some easily understood marks. After that, the automated control unit 24 can characterize or fine-tune the system.

Mission-Specific Target Generation (Off-Line Process)

The module 122 generates mission-specific targets 164 with known product-related information. By imaging and analyzing these targets, the configuration component 74 is able to confirm whether the image capture assembly 22 being characterized is capable of performing the desired mission.

In the case of a mission which involves barcode localization and recognition, the requirements of the image capture assembly 22 can be evaluated from the resolution on the object plane, FOV, and/or image blur (due to undesired motion, vibration . . . ). While this may be achieved using the calibration target alone, having a target 164 which is specific to the store allows the assembly 22 to be specifically characterized for the store in which it will be used. For example, barcode size, encoding type (e.g., EAN-13 vs. Code39), and the like may differ from store to store and these, as well as environmental conditions, such as lighting may influence the desired resolution. For example, as the barcode width increases, the minimal resolution needed for recognition decreases, i.e., it is easier to image and decode a larger barcode. The relationship, however, is often neither linear nor straight-forward. The contrast of the printed barcode also plays a role on the minimal resolution needed. Hence the use of a mission-specific target is an effective way to characterize the resolution capability of the image capture assembly 22 for a given mission. In some embodiments, the mission-specific target(s) may include one or more actual price tags of interest which may be positioned on top of or adjacent the calibration target on the wall. Since the exemplary calibration target has redundancies embedded, there is considerable flexibility on the placement of posting the additional samples 164 on the calibration target 140.

Image Acquisition

The image acquisition module 124 acquires images using the image capture assembly 22 to be characterized at the settings that the imaging system is intended to be used for the retail application. For example, the imaging component 38 may be intended to operate at a distance of 0.5-1 meters away from the shelf face and with direct facing to the shelf face. Accordingly, it is positioned in a similar relationship to the calibration target on the wall. Test images may be acquired over a range of positions which may be used to mitigate errors or adapt the system to position variations in a real mission where a predetermined distance to the shelf face cannot be maintained throughout.

Landmark Detection

The landmark detection module 126 detects the identifiable landmarks 150 on the acquired images (e.g., black dots). This can be achieved with a variety of techniques, such as thresholding on one or more color channels (e.g., the green channel), morphological filtering and connected-component analysis, and thresholding on size, or a combination thereof. In general, each captured image includes only a subset (fewer than all) of the landmarks that are visible on the target. The module 126 therefore keeps track of the images in which a detected landmark was found. The module 126 may output a list of data that corresponds to the pixel location and image ID for each detected landmark 150.

Information Decoding

The image decoding module 128 detects the set(s) of location-encoding marks 158 (colored blocks with text in the example embodiment) on the acquired images and then decodes their corresponding location and/or mission information. In one embodiment, a color-based segmentation method may be used to identify candidate regions that are of approximately the same color as the colored blocks. Morphological filtering, connected-component analysis, and thresholding on size may then be used to further refine the set of candidate regions. Finally, a sub-image of each candidate region with numerical text is analyzed by an OCR engine to extract the digits or other location-encoding information. If the digits match those of the calibration target 146, the corresponding localization information is extracted using the appropriate formula (e.g., Eqn. 1). The output of the module 126 is data that corresponds to the pixel location and encoded location information for each detected location-encoding-mark 158.

Spatial Characterization

The spatial characterization module 130 matches the detected landmarks and detected location-encoding marks output from modules 126, 128, and then derives absolute and relative spatial profile(s) and other characteristics of the image capture assembly 22. In one embodiment, the matching is performed by finding a pair of marks 150, 158 with minimal Euclidean distance in the pixel space and meeting the constraint that the colored block is positioned above the black dot. Due to the cameras often being titled or otherwise angled relative to the x, z plane, the images may be skewed.

For generating a spatial profile corresponding to each of the images acquired, model fitting may be used to find the best projective transformation for the image into real space. Relative characteristics of each image spatial profile, such as extent of vertical overlap or vertical spacing between adjacent FOVs and/or relative center misalignment between each pair of images are also derived. The output of the module 130 may include a set of spatial profiles, e.g., as projection matrices and their relative characteristics. The number of spatial profiles depends on the number of cameras and camera positions used. For example, for a 3-camera, single position assembly, 3 spatial profiles may be generated. For a 2-camera, two position assembly, 4 spatial profiles may be provided. However in this case, two of the spatial profiles may be very close to a translated version of the other two. Also in this case, the amount of translation in the camera positions may be characterized as an additional output. For the application of store profiling discussed above, obtaining individual spatial profiles for each image and determining whether the overlap FOV of adjacent images is great than a threshold value (e.g., zero) or not is generally sufficient for characterizing the image capture assembly 22. However, additional information may be extracted for configuring/reconfiguring the image capture assembly 22 if the configuration has not been determined or optimized or has been adjusted for a different retail application of interest.

Mission Capability Confirmation

The module 132 analyzes the acquired test images to extract information from the example mission-specific targets 164, compares the extracted information with the intended information of the targets 164, and confirms/assesses the capability of the system to perform the intended mission. For detection and decoding, it may reuse the process in landmark detection and information decoding, but here applied to different marks 166 and may employ a different decoding tool. In one embodiment, barcode localization and recognition is employed on the acquired images and a check is performed to determine if all barcodes are correctly recognized. If so, then the capability is confirmed. Additionally, if barcodes are easily recognized, the resolution may be decreased and/or the FOV increased to allow the mission to proceed faster. If the barcodes are not all recognized, the FOV could be decreased (increasing the resolution), or other reconfiguration of the image capture assembly 22, such as adding camera, may be performed. The output of module 132 may be fed to the reconfiguration module 134 to make suggestions for reconfiguration.

Reconfiguration

The module 134 utilizes the characterized spatial profile(s), the knowledge of the parameters of the current configuration, and the knowledge of the system requirements (which may be mission dependent, store dependent, application-dependent etc.) to compute an improved configuration for the image capture assembly 22. For example, if the overlapping FOVs among pairs of images are not evenly distributed, it may be desirable to readjust relative camera positions. The characterized misalignment/offset amounts between cameras can be computed to align them. If the resolution is more than sufficient, FOVs may be increased or the number of cameras or position-translations may be reduced to decrease the mission time or lower the cost. The reconfiguration component may implement a new configuration automatically.

The configuration component 74 thus described may be implemented in a store profile generation system, as described with respect to FIG. 5. However, it also finds application in other systems, such as a system for confirming whether a part of a store display unit complies with a predefined planogram, a system for generating composite images of display units, in other multi-camera/multi-position imaging systems, and the like. As will be appreciated, such a configuration system may include some or all of the components of FIG. 5, including memory 62 and processor 60.

The method illustrated in FIGS. 7 and/or 11 may be implemented in a computer program product that may be executed on a computer. The computer program product may comprise a non-transitory computer-readable recording medium on which a control program is recorded (stored), such as a disk, hard drive, or the like. Common forms of non-transitory computer-readable media include, for example, floppy disks, flexible disks, hard disks, magnetic tape, or any other magnetic storage medium, CD-ROM, DVD, or any other optical medium, a RAM, a PROM, an EPROM, a FLASH-EPROM, or other memory chip or cartridge, or any other tangible medium from which a computer can read and use.

Alternatively, the method(s) may be implemented in transitory media, such as a transmittable carrier wave in which the control program is embodied as a data signal using transmission media, such as acoustic or light waves, such as those generated during radio wave and infrared data communications, and the like.

The exemplary method(s) may be implemented on one or more general purpose computers, special purpose computer(s), a programmed microprocessor or microcontroller and peripheral integrated circuit elements, an ASIC or other integrated circuit, a digital signal processor, a hardwired electronic or logic circuit such as a discrete element circuit, a programmable logic device such as a PLD, PLA, FPGA, Graphical card CPU (GPU), or PAL, or the like. In general, any device, capable of implementing a finite state machine that is in turn capable of implementing the flowchart shown in FIGS. 7 and or 11, can be used to implement the methods described herein. As will be appreciated, while the steps of the method may all be computer implemented, in some embodiments one or more of the steps may be at least partially performed manually.

Example

A prototype system 10 with software forming a configuration component 74 was implemented with a combination of MATLAB and OpenCV C++. The system was used for both characterizing and configuration of an image capture assembly 22 with three cameras and a translation stage 48, providing two position capability, as exemplified in FIG. 3. In some configurations, the translation stage moved all cameras up or down by about 30 cm. In some configurations, the lowermost camera 44 was able to tilt to a position in which the camera lens pointed downward.

The system 10 was intended to cover a store shelf face up to maximal height of about 183 cm. A calibration target 140 was generated using nine units of the template and posted on a wall, covering approximately 206×43 cm. Additionally, actual on-sale price tags used in a real retail application were posted on the calibration target as mission-specific targets 164. The image capture assembly 22 could first be roughly configured using a combination of minimal imaging resolution requirement calculation, knowledge of maximal shelf height, knowledge of the dimension of the mobile base, manual set-up of FOV via camera view-finder, etc.

It can be assumed, for example, that an imaging system consisting of a 3-camera array with 2-positional capability is equivalent to a system with a 6-camera array with cameras that are 30.5 cm apart if their FOVs are evenly distributed and facing orthogonal to the shelf face. A FOV of about 30-36 cm in the short direction of the camera was found to provide sufficient imaging resolution for recognizing a target EAN-13 barcode with a width larger than 2.5 cm. The mobile base for an initial test was about 23 cm in height, while the lowest shelf was at about 18 cm above the floor. For this configuration, the lowest camera did not need to be tilted in order to provide a field of view to capture the lowest shelf. Two camera positions could capture the full height of the shelf face. For a taller mobile base (about 40 cm), the lowest camera could be arranged to point down at an angle and translated vertically, providing two tilted positions for the lowest camera.

After initial configuration of the image capture assembly 22 the method of FIG. 11 was used for acquiring test images (3 cameras, 2 positions) (S206), detecting landmarks and mission-specific marks (S208), decoding location or barcode information (S210), and characterizing the six camera spatial profile (3 camera×2 position) (S212). A representation of the intermediate graphical results of the camera FOVs in the x, z-plane from the MATLAB implementation is shown in FIG. 12. There is a noticeable gap of about 18 cm between the camera 2, first position and the camera 3, first position. This could be manually adjusted, at least partially. However, other characteristics can be captured form the analysis, such as individual differences in camera FOVs, misalignment among cameras, the exact amount of overlap or gaps, amount of distortions due to camera poses, etc., which are not readily detectable manually For example, camera 2, positions 1 and 2, are only marginally overlapped. If the FOV changes even slightly during the mission, a gap could be created. Camera 2 is also offset from the center, relative to the other two cameras and has the smallest FOV. Table 1 shows example raw characteristics of the cameras in the imaging system. From this data, an improved configuration of the cameras can be analytically determined of using the reconfiguration module.

TABLE 1 Example initial characteristics of the cameras in the imaging system center center max min max min Overlap Camera X Z X X Z Z FOV1 FOV2 in Z 1-up −6.42 77.36 3.41 −16.02 84.02 70.66 19.44 13.35 0.96 1-down −6.52 65.05 3.26 −16.05 71.62 58.34 19.31 13.28 1.37 2-up −7.72 53.42 1.56 −16.85 59.71 47.08 18.41 12.62 0.19 2-down −7.80 41.10 1.44 −16.83 47.27 34.80 18.28 12.47 −7.18 3-up −6.40 21.15 4.33 −16.55 27.62 13.63 20.88 13.99 1.71 3-down −6.48 8.95 4.09 −16.50 15.34 1.48 20.59 13.86 −1.48

To derive a modified configuration of the image capture assembly 22, an Excel tool was built that takes inputs from Table 1 and derives a set of parameters for FOVs, camera mounting positions, and translation amount. These parameters could then be fed to a programmable control unit, such as components 76, 78, that adjusts the configuration of the image capture assembly 22. In the prototype system, however, this was achieved through manual adjustment of the image capture assembly 22 based on these suggested parameters. While this was not an ideal solution, the changes implemented (increase FOV of camera 2, lower cameras 1 and 2, change translation amount by computed parameters) increased the coverage, as illustrated in FIG. 13, as well as improving the balance of overlap in Z etc. The reconfigured image capture assembly 22 met the requirements, such as coverage of maximal height, no gap, FOV at the range of 30 to 36 cm for imaging resolution, for the retail applications of interest. The settings could be further optimized by repeating the process.

Table 2 shows characteristics after reconfiguring the image capture assembly 22 according to the computed parameters.

TABLE 2 Example raw characteristics of the cameras in the image capture assembly for second iteration center center max min max min Overlap Camera X Z X X Z Z FOV1 FOV2 in Z 1-up −6.77 65.13 2.97 −16.30 71.70 58.45 19.27 13.25 2.05 1-down −6.87 53.98 2.81 −16.33 60.51 47.32 19.14 13.19 1.20 2-up −7.99 42.16 1.6 −17.35 48.52 47.08 18.96 12.86 1.70 2-down −8.08 31.00 1.44 −17.40 37.36 24.58 18.84 12.78 1.81 3-up −6.46 19.93 4.25 −16.66 26.39 12.40 20.86 13.99 2.88 3-down −6.53 8.87 4.03 −16.58 15.28 1.41 20.62 13.87 −1.48

These experimental results demonstrate that the automated method is beneficial and accurate for characterizing and/or configuring an imaging system for retail applications.

FIGS. 14 and 15 illustrate panoramas of the calibration target 140, before and after reconfiguration of the image capture assembly, which were generated from the computed spatial profiles of the cameras by applying them to the captured images. As will be appreciated, similar panoramas can be generated of a store shelf unit using the computed camera spatial profiles and may optionally be used in the generation of the store profile by stitching together multiple vertical panoramas.

It will be appreciated that variants of the above-disclosed and other features and functions, or alternatives thereof, may be combined into many other different systems or applications. Various presently unforeseen or unanticipated alternatives, modifications, variations or improvements therein may be subsequently made by those skilled in the art which are also intended to be encompassed by the following claims. 

What is claimed is:
 1. A configuration system comprising: a calibration target generation module which generates a spatially-characterized calibration target to be printed, the calibration target comprising a set of machine-readable and visually-identifiable landmarks and associated location-encoding marks which encode known locations of the landmarks; an image acquisition module which acquires a plurality of test images of the printed calibration target from an associated image capture assembly to be spatially characterized; a landmark detection module which detects positions of the landmarks in the acquired test images; an information decoding module which detects the location-encoding marks in the acquired test images and decodes the locations of the landmarks from the detected location-encoding marks; a spatial characterization module which spatially characterizes the image capture assembly, based on the detected positions of the landmarks in the acquired test images and the respective decoded known locations of the landmarks and by computing relative characteristics of at least two of the acquired test images; and a processor which implements the calibration target generation module, image acquisition module, landmark detection module, information decoding module, and spatial characterization module.
 2. The system of claim 1, wherein the calibration target generation module generates a plurality of sections of the target from a template, the sections being combined to form the target.
 3. The system of claim 1, wherein the associated image capture assembly comprises at least one of: a plurality of cameras, each of the cameras capturing at least one of the test images; and a mechanism for providing a plurality of camera positions for at least one camera of the image capture assembly, each of the camera positions of each of the at least one camera corresponding to one of the test images.
 4. The system of claim 1, wherein the computed relative characteristics include an extent of overlap or spacing between respective fields of view for the at least two of the test images.
 5. The system of claim 4, wherein the system further comprises a wheeled mobile base, the image capture assembly being carried by the mobile base.
 6. The system of claim 1, wherein the system comprises the image capture assembly.
 7. The system of claim 1, further comprising a mission-specific target generation module which generates an example of at least one printable mission-specific target, the image acquisition module acquiring at least one test images of the mission-specific target from the associated image capture assembly.
 8. The system of claim 1, further comprising a mission capability confirmation module which assesses a capability of the associated image capture assembly to perform a mission which includes capture of images of a store display unit.
 9. A configuration system comprising: a calibration target generation module which generates a plurality of sections of a spatially-characterized calibration target to be printed from a template, the sections being combinable to form the calibration target, the calibration target comprising a set of machine-readable and visually-identifiable landmarks and associated location-encoding marks which encode known locations of the landmarks, wherein the template provides for an automated update of the location-encoding marks for each subsequent section of the plurality of sections; an image acquisition module which acquires a plurality of test images of the printed calibration target from an associated image capture assembly to be spatially characterized; a landmark detection module which detects positions of the landmarks in the acquired test images; an information decoding module which detects the location-encoding marks in the acquired test images and decodes the locations of the landmarks from the detected location-encoding marks; a spatial characterization module which spatially characterizes the image capture assembly, based on the detected positions of the landmarks in the acquired test images and the respective decoded known locations of the landmarks; and a processor which implements the calibration target generation module, image acquisition module, landmark detection module, information decoding module, and spatial characterization module.
 10. The system of claim 9, wherein the spatial characterization module spatially characterizes the image capture assembly by computing relative characteristics of at least two of the test images.
 11. A configuration system comprising: a calibration target generation module which generates a spatially-characterized calibration target to be printed, the calibration target comprising a set of machine-readable and visually-identifiable landmarks and associated location-encoding marks which encode known locations of the landmarks; an image acquisition module which acquires a plurality of test images of the printed calibration target from an associated image capture assembly to be spatially characterized; a landmark detection module which detects positions of the landmarks in the acquired test images; an information decoding module which detects the location-encoding marks in the acquired test images and decodes the locations of the landmarks from the detected location-encoding marks; a spatial characterization module which spatially characterizes the image capture assembly, based on the detected positions of the landmarks in the acquired test images and the respective decoded known locations of the landmarks; a reconfiguration module which computes a reconfiguration for the associated image capture assembly, based on at least one of the spatial characterization of the image capture assembly and an analysis of a mission-specific target, the reconfiguration for the associated image capture assembly being computed to modify an extent of overlap or spacing between respective fields of view for at least two of the test images; and a processor which implements the calibration target generation module, image acquisition module, landmark detection module, information decoding module, spatial characterization module, and reconfiguration module.
 12. The system of claim 11, wherein the reconfiguration for the associated image capture assembly includes a modification to at least one of: a plurality of cameras of the image capture assembly, each of the cameras capturing at least one of the test images, and a mechanism for providing a plurality of camera positions for at least one camera of the image capture assembly, the positions including a first position and a second position, vertically-spaced from the first position, each of the camera positions of each of the at least one camera corresponding to one of the test images.
 13. A configuration method comprising: providing a spatially-characterized calibration target, the calibration target comprising a set of machine-readable, visually-identifiable landmarks and associated location-encoding marks which encode known locations of the landmarks; and for at least one iteration: acquiring a plurality of test images of the printed calibration target at a plurality of vertically-spaced positions with an image capture assembly to be spatially characterized, detecting positions of the landmarks in the acquired test images, decoding the locations of the landmarks from the detected location-encoding marks detected in the acquired test images, and with a processor, spatially characterizing the image capture assembly, based on the positions of the landmarks in the acquired test images and the decoded known locations of the landmarks, the spatial characterization comprising computing relative characteristics of at least two of the test images.
 14. The method of claim 13, wherein the providing of the spatially-characterized calibration target comprises generating each of a plurality of sections of the target from a template and joining the sections together to form the target.
 15. The method of claim 13, wherein the acquiring a plurality of test images of the printed calibration target at a plurality of vertically-spaced positions comprises at least one of: capturing an image of the test with each of a plurality of cameras of the image capture assembly; and moving at least one camera of the image capture assembly from a first camera positions having a first field of view; to a second position with a second field of view, the second field of view being vertically spaced from the first field of view.
 16. The method of claim 13, wherein the computing of the relative characteristics includes computing an extent of overlap or spacing between respective fields of view for the at least two of the test images.
 17. The method of claim 13, further comprising computing a reconfiguration for the image capture assembly, based on the spatial characterization of the image capture assembly.
 18. The method of claim 13, wherein the computing of the reconfiguration comprises computing of a reconfiguration predicted to modify an extent of overlap or spacing between respective fields of view for at least two of the test images in a subsequent one of the iterations.
 19. The method of claim 13, further comprising generating an example of at least one printable mission-specific target, the image acquisition comprising acquiring at least one test image of the mission-specific target from the image capture assembly.
 20. The method of claim 19, further comprising assessing a capability of the associated image capture assembly to perform a mission which includes capture of images of a store display unit based on the acquired at least one test image of the mission-specific target.
 21. A method for configuring an imaging system having a plurality of vertically-spaced fields of view comprising: with a template, generating sections of a calibration target, each of the sections of the calibration target comprising a set of machine-readable and visually-identifiable landmarks and associated location-encoding marks which encode known locations of the landmarks; joining the sections together to form the calibration target; acquiring a plurality of test images of the printed calibration target at a plurality of vertically-spaced positions with an image capture assembly; detecting positions of the landmarks in the acquired test images; decoding the locations of the landmarks from the detected location-encoding marks detected in the acquired test images; with a processor, reconfiguring the image capture assembly comprising computing a reconfiguration predicted to modify an extent of overlap or spacing between respective fields of view for at least two test images when the acquisition of the test images is repeated, based on the positions of the landmarks in the acquired test images and the decoded known locations of the landmarks; and for the reconfigured image capture assembly, repeating the acquiring of the plurality of test images, detecting positions of the landmarks, and decoding the locations of the landmarks.
 22. The method of claim 21, wherein the template provides for an automated update of the location-encoding marks for each subsequent section of the plurality of sections. 